JP2013501201A - Proportional poppet valve with integrated check valve - Google Patents

Abstract

The poppet valve assembly includes a body having a first shaft end and a second shaft end. The first shaft end includes a tapered surface adapted for sealing connection with a valve seat. The second shaft end defines a metering orifice. The body defines a passage that includes an opening at the first shaft end and is in fluid communication with the metering orifice. The passage includes a check valve seat. A check valve is disposed in the passage. The check valve is adapted for sealing connection with the check valve seat.

Description

  The present invention relates to poppet valve assemblies.

  Valve assemblies are used in a variety of applications, including off-highway agriculture and construction machinery (eg, wheel loaders, skid steers, combines, etc.). In some applications, the valve assembly is used to control the flow rate supplied to a means such as a bucket or boom. The means desirably has a valve assembly capable of supporting some load such that the load can be supported over a long period of time.

  The present disclosure relates to poppet valve assemblies. The poppet valve assembly includes a body having a first shaft end and a second shaft end. The first shaft end includes a tapered surface adapted for sealing connection with the valve seat. The second shaft end defines a metering orifice. The body defines a passage having an opening at the first shaft end and in fluid communication with the metering orifice. The passage includes a check valve seat. The check valve is disposed in the passage. The check valve is adapted for sealing connection with the check valve seat.

  Another aspect of the present disclosure relates to a valve assembly. The valve assembly includes a main stage valve assembly. The main stage valve assembly includes a housing defining a first flow path, a second flow path, a valve bore and a load holding cavity. The valve bore includes a valve seat. The valve bore is in fluid communication with the first and second flow paths. The valve seat is disposed between the first and second flow paths. The load holding cavity is selectively in fluid communication with the second flow path. The main stage valve assembly further includes a poppet valve assembly disposed in the valve bore. The poppet valve assembly includes a poppet valve that is adapted for coupling with a valve seat. The poppet valve has a body that defines a passage through the body. The passage includes a check valve seat and provides fluid communication between the first flow path and the load holding cavity. The check valve is disposed in the passage of the poppet valve. The check valve is adapted to reduce fluid leakage in the passage from the load holding cavity to the first flow path.

  Another aspect of the present disclosure relates to a valve assembly. The valve assembly includes a pilot stage valve assembly, a middle stage valve assembly in fluid communication with the pilot stage valve assembly, and a main stage valve assembly in fluid communication with the middle stage valve assembly. The main stage valve assembly includes a housing defining an inlet flow path, an outlet flow path, a valve bore and a load holding cavity. The valve bore includes a valve seat. The valve bore is in fluid communication with the inlet and outlet channels. The valve seat is disposed in a valve bore between the inlet and outlet channels. The middle stage valve assembly provides fluid communication between the load holding cavity and the outlet flow path. The main stage valve assembly further includes a poppet valve assembly disposed in the valve bore. The poppet valve assembly includes a poppet valve that is adapted for coupling with a valve seat. The poppet valve has a body that defines a passage through the body. The passage includes a check valve seat and provides fluid communication between the inlet flow path and the load holding cavity. The check valve is disposed in the passage of the poppet valve. The check valve is adapted to reduce leakage of fluid passing through a passage in a direction from the load holding cavity to the inlet flow path.

  Various additional disclosures will be clarified in the description that follows. These disclosures are associated with individual features and combinations of features. It should be understood that each of the foregoing general description and the detailed description that follows is nothing other than exemplary and illustrative, and is not constrained to a broad concept based on the embodiments disclosed herein. is there.

1 is a schematic view of a valve assembly having exemplary features in a form corresponding to the principles of the present disclosure. FIG. FIG. 2 is a fragmentary cross-sectional view of a main stage valve assembly applied for use with the valve assembly of FIG. FIG. 3 is a perspective view of a poppet valve adapted for use with the main stage valve assembly of FIG. 2. FIG. 4 is a side view of the poppet valve of FIG. 3. It is sectional drawing by the line 5-5 in the poppet valve of FIG. FIG. 4 is a partial enlarged view of a nozzle of the poppet valve of FIG. 3. FIG. 3 is a cross-sectional view of a poppet valve assembly adapted for use with the main stage valve assembly of FIG. 2.

  Exemplary embodiments of the present disclosure will be described in detail with reference to the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or corresponding features.

  Referring now to FIG. 1, a valve assembly designated 10 is shown. In one aspect of the present disclosure, the valve assembly 10 includes three stages: a pilot stage valve assembly 12, a middle stage valve assembly 14, and a first main stage valve assembly 16a.

  In one aspect of the present disclosure, the pilot stage valve assembly 12 is a proportional valve that includes a pilot stage spool valve 18 and a housing 20. The pilot stage spool valve 18 is disposed in the bore of the housing 20 so that the pilot stage spool valve 18 can slide axially in the bore of the housing 20.

  The pilot stage valve assembly 12 includes a plurality of centering springs 22. A plurality of centering springs 22 are adapted to center the pilot stage spool valve 18 in the bore of the housing 20.

In one aspect of the present disclosure, the pilot stage valve assembly 12 is a four-way valve. The pilot stage valve assembly 12 includes a fluid inlet port 24, a fluid return port 26, a first control port 28 and a second control port 30. In other aspects of the present disclosure, the pilot stage valve assembly 12 is a three position valve. The pilot stage valve assembly 12 includes a neutral position P _PN , a first position P _P1, and a second position P _P2 .

The neutral position P _PN , the first and second control ports 28, 30 are in fluid communication with the fluid return port 26. In the first position _PP1 , the first control port 28 is in fluid communication with the fluid inlet port 24 while the second control port 30 is in fluid communication with the fluid return port 26. In the second position _PP2 , the first control port 28 is in fluid communication with the fluid return port 26 while the second control port 30 is in fluid communication with the fluid inlet port 24.

As with a proportional valve, the axial position of pilot stage spool valve 18 within the bore of housing 20 controls the flow rate of fluid through pilot stage valve assembly 12. The pilot stage valve assembly 12 is an electronic actuator adapted to move the pilot stage spool valve 18 in the bore of the housing 20 in the axial direction between the neutral position P _PN and the first and second positions P _P1 , P _P2. Includes 32. In one aspect of the present disclosure, the electronic actuator 32 is a voice coil.

  The electronic actuator 32 operates in response to an electronic signal 34 (shown in phantom in FIG. 1) received from the computing device 36. In one aspect of the present disclosure, the computing device 36 provides an electronic signal 34 in response to various input signals.

  The first and second control ports 28, 30 of the pilot stage valve assembly 12 are in fluid communication with the middle stage valve assembly 14. In one aspect of the present disclosure, the middle stage valve assembly 14 is a 3-position, 4-way proportional valve. In other aspects of the present disclosure, the middle stage valve assembly 14 is a two-position, two-way proportional valve.

  The middle stage valve assembly 14 includes a middle stage spool valve 40 and a housing 42. The middle stage spool valve 40 is disposed within the bore of the housing 42 so that the middle stage spool valve 40 can slide within the bore of the housing 42.

  The middle stage spool valve 40 includes a first shaft end portion 44 and a second shaft end portion 46 disposed on the opposite side thereof. At the same time as the second spring 48b acts on the second shaft end 46, the first spring 48a acts on the first shaft end 44 of the middle stage spool valve 40. The first and second springs 48 a, 48 b are adapted to center the middle stage spool valve 40 in the bore of the housing 42.

  The axial position of the middle stage spool valve 40 in the bore of the housing 42 is controlled by the fluid pressure acting on one of the first and second shaft ends 44,46. In one aspect of the present disclosure, the first control port 28 of the pilot stage valve assembly 12 is coupled to the middle stage spool valve 40 while the second control port 30 of the pilot stage valve assembly 12 is in fluid communication with the second shaft end 46. The first shaft end 44 is in fluid communication.

  The middle stage valve assembly 14 further includes a position sensor 50. In one aspect of the present disclosure, the position sensor 50 is a linear variable displacement transducer (LVDT). The position sensor 50 detects the position of the middle stage spool valve 40 in the bore of the housing 42. The position sensor 50 transmits a signal 52 to the computing device 36 that uses the position data from the position sensor 50 to activate the electronic actuator 32 of the pilot stage valve assembly 12. The position of the middle stage valve assembly 14 will be described later.

  In one aspect of the present disclosure, the middle stage valve assembly 14 is selectively in fluid communication with the first main stage valve assembly 16a. In another aspect of the present disclosure, the middle stage valve assembly 14 is selectively in fluid communication with the first main stage valve assembly 16a and the second main stage valve assembly 16b, and the second main stage valve assembly 16b is connected to the first main stage valve assembly 16b. The structure is substantially similar to the stage valve assembly 16a. Since the second main stage valve assembly 16b has a structure similar to that of the first main stage valve assembly 16a, the description of the second main stage valve assembly 16b is omitted here for the purpose of simplifying the description.

  The first main stage valve assembly 16a will be described with reference to FIGS. The first main stage valve assembly 16a includes a valve housing 60 and a poppet valve assembly generally designated 62.

  Valve housing 60 defines a valve bore 64 having a central axis 66. Valve bore 64 is adapted to receive poppet valve assembly 62. Poppet valve assembly 62 is adapted for axial movement within valve bore 64 along central axis 66.

  The valve bore 64 includes a first end 68 and a second end 70 disposed on the opposite side. The valve bore 64 defines a first cavity 72, a second cavity 74 and a load holding cavity 76. The first cavity 72 is disposed at the first end 68 of the valve bore 64. The second cavity 74 is disposed between the first and second ends 68 and 70. The load holding cavity 76 is disposed at the second end 70.

  Valve housing 60 communicates with first flow path 78 in fluid communication with first cavity 72 of valve bore 64, second flow path 80 in fluid communication with second cavity 74 of valve bore 64, and load holding cavity 76 of valve bore 64. A third flow path 82 in fluid communication is further defined. The valve housing 60 further defines a fourth flow path 84. The fourth flow path 84 is in fluid communication with the second flow path 80 through the middle stage valve assembly 14 and is selectively in fluid communication with the third flow path 82. In one aspect of the present disclosure, the second flow path 80 is an outlet flow path and the first flow path 78 is an inlet flow path.

  The valve bore 64 includes a valve seat 86. The valve seat 86 is disposed at the first end 68 of the valve bore 64. In one aspect of the present disclosure, the valve seat 86 is disposed at the intersection of the first flow path 78 and the valve bore 64.

  The valve seat 86 of the valve bore 64 is adapted for selective sealing connection with the poppet valve 60. In one aspect of the present disclosure, the valve seat 86 is tapered so that the inner diameter of the valve seat 86 decreases as the distance along the central axis 66 from the valve seat 86 to the second end 70 increases. In other aspects of the present disclosure, the valve seat 86 is generally formed in a truncated cone shape.

  Poppet valve assembly 62 includes a poppet valve and check valve 92, indicated generally at 90. In one aspect of the present disclosure, the check valve 92 is disposed on the poppet valve 90.

  With reference to FIGS. 3-6, a poppet valve 90 is shown. Poppet valve 90 includes a body having a central axis 96 generally indicated at 94 and extending through the center of body 94. The body 94 includes a first shaft end portion 98 and a second shaft end portion 100 disposed on the opposite side. In one aspect of the present disclosure, the first shaft end portion 98 has an outer diameter D1 that is smaller than the outer diameter D2 of the second shaft end portion 100.

  The first shaft end portion 98 includes a first end surface 102 and a first circumferential surface 104. The first circumferential surface 104 is generally cylindrical. In one aspect of the present disclosure, the first circumferential surface 104 includes a tapered surface 106. The tapered surface 106 is adapted for selective seal coupling of the valve bore 64 with the valve seat 86. The tapered surface 106 is disposed adjacent to the first end surface 102. The tapered surface 106 is generally formed in a frustoconical shape and has an outer diameter that increases as the axial distance from the first end surface 102 to the tapered surface 106 increases.

  In one aspect of the present disclosure, the first shaft end 98 defines an annular groove 108. In the illustrated embodiment of FIGS. 1-6, the annular groove 108 is disposed between the first end surface 102 and the tapered surface 106. In one aspect of the present disclosure, the annular groove 108 improves the grindability of the tapered surface 106 during the manufacturing process of the poppet valve 90.

  In other aspects of the present disclosure, the first shaft end 98 further defines a cavity 112. The cavity 112 includes an opening 114 in the first end face 102.

  The second shaft end portion 100 includes a second end surface 116 and a second circumferential surface 118. In one aspect of the present disclosure, the second end surface 116 includes a spring guide 120. The spring guide 120 is generally formed in a cylindrical shape and extends outward from the central position on the second end face 116. The outer diameter of the spring guide 120 is set to a size smaller than the inner diameter of the spring 122 so that the spring guide 120 fits within the inner diameter of the bore of the spring 122 (best shown in FIG. 2). In one aspect of the present disclosure, the spring 122 is a coil spring.

  The second circumferential surface 118 is generally formed in a cylindrical shape. In one aspect of the present disclosure, the second circumferential surface 118 defines a plurality of grooves 123. In the illustrated embodiment, the three grooves 123 are defined by the second circumferential surface 118. The groove 123 extends around the second circumferential surface 118 and is adapted to the pressure balance of the poppet valve 90 within the valve bore 64.

  The second circumferential surface 116 defines a hole 124 that extends radially from the second circumferential surface 118 into the body 94. The second circumferential surface 118 further defines a metering slot 126 that extends axially outward from the hole 124 toward the second end surface 116.

  The body 94 of the poppet valve 90 defines a passage 128. The passage 128 is adapted to provide fluid communication between the first flow path 78 and the load holding cavity 76. As described below, the flow through passage 128 and the flow through middle stage valve assembly 14 cooperate to determine the axial position of poppet valve assembly 62 within valve bore 64 of housing 60.

  The passage 128 extends generally axially through the first and second end faces 102, 116. In one aspect of the present disclosure, the passage 128 is generally parallel to the central axis 96 of the body 94. In other aspects of the present disclosure, the passage 128 is offset from the central axis 96 of the body 94. In other aspects of the present disclosure, the passage 128 is generally disposed in the same orientation as the central axis 96 of the body 94.

  The passage 128 includes a first portion 130 and a second portion 132. The first portion 130 includes an opening 133 defined by the first end surface 102 and extends from the cavity 12 of the first shaft end portion 98 in the first axial direction into the body 94 of the poppet valve 90 and at the same time the second portion. 132 extends from the second end face 116 into the body 94 in the opposite second axial direction. In one aspect of the present disclosure, the first and second portions 130, 132 are disposed on the same axis.

  The first portion 130 includes an inner diameter that is smaller than the inner diameter of the second portion 132. The first and second portions 130, 132 of the passage 128 cooperate to define a check valve seat 134. Check valve seat 134 is adapted for selective seal coupling with check valve 92 adapted to provide a one-way flow through passage 128. In one aspect of the present disclosure, the check valve seat 134 includes a frustoconical surface having an inner diameter that decreases as the distance from the second end surface 116 increases. In other aspects of the present disclosure, the check valve seat 134 is generally perpendicular to an axis extending through the passage 128.

  The first portion 130 of the passage 128 is in fluid communication with the cavity 112. The second portion 132 of the passage 128 is in fluid communication with the metering slot 126. In one aspect of the present disclosure, fluid communication between the metering slot 126 and the second portion 132 of the passage 128 is established through a hole 124 that extends from the second circumferential surface 118 to the second portion 132 of the passage 128.

  Referring to FIG. 6, poppet valve 90 further defines an orifice 136. The orifice 136 extends through the second end face 116 and the axial end 138 of the metering slot 126. The inner diameter of the orifice 136 allows the fluid communication between the metering slot 126 and the load holding cavity 76 to be limited when the poppet valve assembly 62 is located in the seated position (see FIGS. 1 and 2). Provided.

  The assembly of the poppet valve assembly 62 will be described with reference to FIG. The check valve 92 is disposed in the second portion 132 of the passage 128. The plug assembly 136 is then inserted into the second portion 132 of the passage 128. The plug assembly 136 includes a spring 138 and a plug 140.

  The spring 138 includes a first end 142 and a second end 144 disposed on the opposite side. The first end 142 of the spring 138 is coupled to the spring seat 146 on the plug 140 while the second end 144 is coupled to the check valve 92. By arranging the spring 138 between the plug 140 and the check valve 92, the check valve 92 is urged into the check valve seat 134.

  The plug 140 of the plug assembly 136 includes a first shaft portion 148 and a second shaft portion 150. The first shaft portion 148 includes a spring seat 146 and defines a plurality of male threads on the outer circumferential surface 152. The male thread of the first shaft portion 148 is adapted for screwing with a plurality of female threads defined by the second portion 132 of the passage 128.

  The second shaft portion 150 extends outward from the first shaft portion 148. The outer diameter of the second shaft portion 150 is smaller than the outer diameter of the first shaft portion 148 and smaller than the inner diameter of the spring 138. The second shaft portion 150 is adapted to prevent the check valve 92 from becoming too far from the check valve seat 134.

  The plug 140 is inserted into the passage 128 so that the spring 138 surrounds the periphery of the second shaft portion 150. The plug 140 is fitted into the second portion 132 of the passage 128.

  The assembly of the first main stage valve assembly 16a will be described with reference to FIG. The poppet valve assembly 62 has a first shaft end 98 of the poppet valve 90 disposed at a first end 68 of the valve bore 64 of the housing 60 and a second shaft end 100 of the poppet valve 90 is a second end of the valve bore 64. It is inserted into the valve bore 64 of the housing 60 so as to be arranged in the part 70.

  With the poppet valve assembly 62 positioned in the valve bore 64, the spring 122 is inserted into the second end 70 of the valve bore 64. In the spring 122, the first end 154 of the spring 122 is adjacent to the second end surface 116 of the second shaft end 100 of the poppet valve 90, and the inner diameter of the spring 122 is the spring of the second shaft end 100 of the poppet valve 90. The guide 120 is inserted so as to surround the periphery.

  The end plug 160 is then inserted into the second end 70 of the valve bore 64 of the housing. The end plug 160 includes a shaft end portion 162. The shaft end 162 defines a spring cavity 164. The spring cavity 164 is adapted to receive the second end 166 of the spring 122.

  In one aspect of the present disclosure, the end plug 160 includes a plurality of male threads. The male thread is adapted for threaded connection with a plurality of female threads defined by the second end 70 of the valve bore 64. As the end plug 160 is inserted into the second end 70 of the valve bore 64, the spring 122 is compressed between the second shaft end 100 of the poppet valve 90 and the end plug 160. This compression of the spring 122 between the second shaft end 100 of the poppet valve 90 and the end plug 160 urges the poppet valve 90 into the valve seat 86.

Referring to FIG. 1, the middle stage valve assembly 14 includes a neutral position P _MN , a first position P _M1, and a second position P _M2 . In the neutral position P _MN , the middle stage valve assembly 14 is adapted to selectively block fluid communication between the load holding cavity 76 of the poppet valve assembly 16 and the second flow path 80 of the poppet valve assembly 16. . With the fluid communication between the load holding cavity 76 and the second flow path 80 blocked, the poppet valve assembly 62 is held by fluid pressure with the tapered surface 106 positioned at the seating position where the valve seat 86 is seated. Is done. With the tapered surface 106 seated on the valve seat 86, fluid communication between the first flow path 78 and the second flow path 80 is prevented.

In the first position _PM1 , the middle stage valve assembly 14 is adapted to provide fluid communication between the load holding cavity 76 and the second flow path 80 of the first main stage valve assembly 16a. In this position, the poppet valve assembly 62 is movable axially within the valve bore 64. When the flow through the passage 128 is less than the flow through the middle stage valve assembly 14, the tapered surface 106 of the poppet valve assembly 62 is moved away from the valve seat 86 by a clearance between the tapered surface 106 and the valve seat 86. Movement in one axis direction is caused. As this clearance increases, the amount of fluid communication between the first flow path 78 and the second flow path 80 increases. If the flow through the passage 128 is equal to the flow through the middle stage valve assembly 14, the axial position of the poppet valve assembly 64 is held at a constant axial position. If the flow through the passage 128 exceeds the flow through the middle stage valve assembly 14, the poppet valve assembly 62 moves toward the valve seat 86 to reduce the clearance between the tapered surface 106 and the valve seat 86. As this clearance decreases, the amount of fluid communication between the first flow path 78 and the second flow path 80 decreases.

  The flow rate through the passage 128 is primarily determined by the size of the opening formed between the metering orifice 126 and the recess 168 in the second end 70 of the valve bore 64. As the opening between metering orifice 126 and recess 168 increases, the flow rate through passage 128 increases. In the seated state, the metering orifice 126 of the poppet valve 90 is completely covered by the valve bore 64. In this situation, fluid can flow through the orifice 136 and into the load holding cavity 76 through the passage 128 while there is an opening between the metering orifice 126 and the recess 168.

In one aspect of the present disclosure, the middle stage valve assembly 14 is a proportional valve assembly. As a result, the flow rate through the middle stage valve assembly 14 is proportional to the axial position of the middle stage spool valve 40 in the bore of the housing 42. As middle stage spool valve 40 approaches the first position P _M1, flow rate through the middle stage valve assembly 14 is increased.

In the second position _PM2 , the middle stage valve assembly 14 is configured so that the fluid holding cavity 76 and the second holding passageway and the first stage valve assembly 14a are closed while fluid communication between the load holding cavity 76 and the second flow path 80 of the first main stage valve assembly 16a is blocked. 2. Fluid communication with the second flow path of the main stage valve assembly 16b. Since the structures of the second main stage valve assembly 16b and the first main stage valve assembly 16a are similar, the operation of the middle stage valve assembly 14 at the second position P _M2 is the middle stage valve assembly at the first position P _M1 . Similar to 14 actions.

The operation of the valve assembly 10 will be described with reference to FIGS. In response to the input signal and the signal 52 from the position sensor 50, the microcontroller 36 transmits an electronic signal 34 to the electronic actuator 32 of the pilot stage valve assembly 12. In this scenario, the pilot stage valve assembly 12 is operated to the second position _PP2 . In the second position P _P2 , the second control port 30 of the pilot stage valve assembly 12 is in fluid communication with the fluid inlet port 24 while the first control port 28 is in fluid communication with the fluid return port 26.

With the pilot stage valve assembly 12 in the second position P _P2 , fluid passes through the pilot stage valve assembly 12 while some fluid acting on the first shaft end 44 of the middle stage spool valve 40 is discharged. And flows to the second shaft end portion 46 of the middle stage spool valve 40. The fluid acting on the second shaft end 46 of the middle stage spool valve 40 moves the middle stage valve assembly 14 to the first position P _P1 .

With the middle stage valve assembly 14 moved to the first position _PP1 , the load holding cavity 76 of the poppet valve assembly 16 is in fluid communication with the second flow path 80. With the load holding cavity 76 of the poppet valve assembly 16 in fluid communication with the second flow path 80, the fluid pressure acting on the first end surface 102 of the poppet valve 90 is such that the tapered surface 106 of the poppet valve 90 is the valve of the valve bore 64. The poppet valve 90 is moved along the central axis 66 so that the coupling to the seat 86 can be released or separated. In the state where the poppet valve 90 is separated from the valve seat 86, fluid communication is established between the first flow path 78 and the second flow path 80.

In other scenarios, the pilot stage valve assembly 12 is in the neutral position _PPN . In the neutral position P _PN , fluid is discharged from each of the first and second shaft ends 44, 46 of the middle stage spool valve 40 so that the middle stage valve assembly 14 is positioned in the neutral position P _PN . As described above, in the middle stage valve assembly 14 is in the neutral position P _PN state, the poppet valve assembly 62 is held in a seated position by the fluid pressure, thereby, between the first and second flow paths 78, 80 Fluid communication is blocked.

A check valve 92 disposed integrally with the body 94 of the poppet valve 90 allows one-way flow between the first flow path 78 and the load holding cavity 76. In one aspect of the present disclosure, the check valve 92 prevents fluid from flowing in a direction from the load holding cavity 76 toward the first flow path 78. Check valve 92 is adapted to prevent fluid leakage through passage 128. Leakage of the fluid flowing from the load holding cavity 76 in a direction toward the first flow path 78, while the middle stage valve assembly 14 is in the neutral position P _PN, unintended unseated from the valve seat 86 of the poppet valve assembly 62 Will result.

  Various modifications and variations of this disclosure within the scope and spirit of this disclosure will become apparent to those skilled in the art and the scope of this disclosure may be unreasonably illustrated in the illustrated implementations disclosed herein. It should be understood that it is not limited to form.

Claims (20)

Including body and check valve,
The body is
A first shaft end portion and a second shaft end portion, the first shaft end portion having a tapered surface adapted for sealing connection with a valve seat, and the second shaft end portion defining a metering orifice. The body includes an opening at the first shaft end and defines a passage in fluid communication with the metering orifice, the passage including a check valve seat;
The check valve is
A poppet valve assembly disposed in the passage and adapted for sealing connection with the check valve seat. The poppet valve assembly of claim 1, wherein the second shaft end includes a circumferential surface defining the metering orifice. The poppet valve assembly of claim 1, wherein the second shaft end includes an end face defining an orifice in fluid communication with the passage. The poppet valve assembly according to claim 3, wherein an end surface of the second shaft end portion includes a spring guide extending outward from the end surface. The poppet valve assembly of claim 1, wherein the passage is offset from a central axis of the body. The poppet valve assembly of claim 1, wherein the check valve is coupled to the check valve seat by being biased by a spring. The poppet valve assembly according to claim 1, wherein the tapered surface is formed in a truncated cone shape. A main stage valve assembly including a housing and a poppet valve assembly;
The housing is
A first flow path;
A second flow path;
A valve bore having a valve seat in fluid communication with the first and second flow paths and disposed between the first and second flow paths;
A load holding cavity in selective fluid communication with the second flow path;
Define
The poppet valve assembly is
Arranged within the valve bore, the poppet valve assembly includes a poppet valve and a check valve, the poppet valve being adapted for coupling with the valve seat, the poppet valve defining a passage through the body Having a body, the passage having a check valve seat, the passage providing fluid communication between the first flow path and the load holding cavity;
The check valve is disposed in the passage of the poppet valve, and the check valve is adapted to reduce leakage of fluid passing through the passage in a direction from the load holding cavity toward the first flow path. Check valve characterized by that. The passage includes a first portion in fluid communication with the first flow path and a second portion in fluid communication with the second flow path, wherein the first portion is smaller than an inner diameter of the second portion. 9. The valve assembly of claim 8, wherein the valve assembly has an inner diameter. 9. The valve assembly of claim 8, wherein the passage is offset from a central axis of the body of the poppet valve. The body of the poppet valve includes a first shaft end and a second shaft end disposed on the opposite side, the first shaft end being adapted for coupling with the valve seat, 9. The valve assembly of claim 8, wherein the second shaft end defines a metering orifice in fluid communication with the passage. A middle stage valve assembly in fluid communication with the poppet valve assembly, wherein the middle stage valve assembly is adapted to provide fluid communication between the load holding cavity and the second flow path; 9. A valve assembly according to claim 8, wherein: The valve assembly of claim 12, wherein the middle stage valve assembly is a 4-way-3 position proportional valve. 9. The valve assembly according to claim 8, wherein the first channel is an inlet channel, and the second channel is an outlet channel. A pilot stage valve assembly, a middle stage assembly, a main stage assembly, and a poppet valve assembly;
The middle stage assembly is in fluid communication with the pilot stage valve assembly;
The main stage assembly is in fluid communication with the middle stage assembly, the main stage assembly including a housing defining an inlet flow path, an outlet flow path, a valve bore, and a load holding cavity;
The valve bore has a valve seat, the valve bore is in fluid communication with the inlet and outlet channels, and the valve seat is disposed within the valve bore between the inlet and outlet channels;
The middle stage assembly provides fluid communication between the load holding cavity and the outlet channel;
The poppet valve assembly is disposed within the valve bore, the poppet valve assembly including a poppet valve and a check valve;
The poppet valve is adapted for coupling with the valve seat, and the poppet valve defines a passage adapted to provide fluid communication through the body between the inlet flow path and the load holding cavity. Having a body, the passage includes a check valve seat;
The check valve is disposed in a passage of the poppet valve, and the check valve is adapted to reduce leakage of fluid passing through the passage in a direction from the load holding cavity toward the inlet flow path. A valve assembly characterized by. The valve assembly of claim 15, wherein the pilot stage valve assembly includes an electronic actuator. The valve assembly of claim 16, wherein the electronic actuator is a voice coil. 16. The valve assembly of claim 15, wherein the pilot stage valve assembly supplies fluid to at least one end of the middle stage spool valve of the middle stage valve assembly to operate the middle stage valve assembly. The body of the poppet valve includes a first shaft end portion and a second shaft end portion disposed on the opposite side, and the first shaft end portion is adapted to be coupled to the valve seat, and The valve assembly of claim 15, wherein the shaft end defines a metering orifice in fluid communication with the passage. The valve assembly of claim 15, wherein the passage is offset from a central axis of the body.

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